FR2875952A1 - INTEGRATED ANTENNA SYSTEM FOR SPACE TELECOMMUNICATIONS FOR MOBILE TERRESTRIAL STATIONS (SATCOMS) - Google Patents

Abstract

Antenna system integrated for telecommunications comprising: at least one antenna (10) substantially flat and circular equipped with an axis of rotation (12) coinciding with its axis, the antenna (10) being secured to a support comprising itself an axis of rotation (11), the axis of rotation (12) of the antenna is inclined at an angle θ relative to the axis of rotation (11) of the antenna support and the antenna beam ( 13) makes an angle φ with respect to the axis of rotation of the antenna.

Description

The invention relates in particular to an integrated antenna system of

  space telecommunications for mobile earth stations (Satcom). It can also be used in related fields, such as radars, radio-relay systems, whenever the antenna system is moving relative to its carrier.

  In space communications in C, X, Ku, Ka, Q, etc. bands, with existing geostationary satellites, mobile earth stations are assumed to have an agile antenna automatically pointed at the traffic satellite, regardless of the position of the satellite. in the sky (all elevations from 0 to 90 degrees, all deposits from 0 to 360 degrees).

  In the description the directions of vertical and horizontal are referenced in the figures. They relate for example to a soil assumed horizontal and plane noted S, or to the place on which is arranged the antenna.

  Figure 1 shows an example of antennal system usual according to the prior art. The antenna is a motorized parabolic antenna 1, represented here with its main reflector 2 and its source 3. The assembly is protected by a radome 4. FIG. 1 shows the antenna in 3 elevation positions, respectively a horizontal position , a 45 degree position and a vertical position. The internal volume of the radome 4 is mainly occupied by the antenna 1 and its movement. Proportionately, there is therefore little room for equipment associated with the antenna, such as motorization, power amplifier, low noise amplifier, transpositions and all the equipment usually associated with the operation of an antenna. antenna. Some of this equipment is sometimes moved to other areas of the station, often in an inconvenient way.

  Another solution according to the state of the prior art is to use a scanning antenna 5, as shown in Figure 2. This type of antenna has such properties as being flat and being able to detach its beam electronically. along an axis A. FIG. 2 shows an antenna performing an electronic scanning in elevation 6 and a mechanical misalignment in bearing 7. With respect to the antenna of FIG. 1, there is no longer any antenna deflection. Comparing Figure 1 and Figure 2, we see that much of the volume initially occupied by the deflection of the antenna is released and therefore available (volume referenced 8 in the figure).

  This solution nevertheless encounters difficulties relating to the electronic scanning antenna; namely, cost, performance, etc. The antennal system according to the invention resides on a new approach judiciously using a flat antenna whose antenna beam is fixed but remote from the mechanical axis of the antenna, the latter being also inclined with respect to a main mechanical axis.

  The invention relates to an integrated antennal system for telecommunications comprising at least one substantially flat and circular antenna equipped with an axis of rotation coinciding with its axis, the antenna being secured to a support comprising itself a rotational axis characterized in that the axis of rotation of the antenna is inclined at an angle 8 with respect to the axis of rotation of the antenna support and the antenna beam is at an angle cp with respect to the axis of rotation of the antenna.

  The diameter of the antenna is for example chosen according to the communication application.

  The angle 8 is for example equal to 45 degrees with respect to a second axis of rotation (axis of rotation of the support) substantially vertical, and the angle cp is equal to 45 degrees. The assembly thus presents the property by rotation of each of the angles and according to the values taken to cover the half-angle located above the horizontal by the antenna beam.

  The antennal system according to the invention has the decisive advantage of using a simple fixed beam passive flat antenna whose design can be optimized for the inclination of the retained beam. The radio performance in terms of antenna gain in the beam axis, as well as off-axis radiation in terms of secondary lobes, are then optimal and kept constant regardless of the desired pointing. The antennal system according to the invention also presents the advantage of being compact and integrated. The rotation along the two axes makes it possible to cover a significant pointing domain. The volume initially required for the movement of the dish is released to leave room for equipment associated with the antenna.

  Other features and advantages of the invention will become more apparent on reading the following description of an exemplary embodiment given by way of illustration and in no way limiting attached to the figures which represent: FIG. 1 an example of an antenna system according to FIG. 2 shows a compact electronic scanning antenna solution according to the prior art. FIG. 3 is an example of an antenna illustrating the principle implemented by the invention. FIG. 4A is a sectional view and FIG. 4B is a perspective view of an alternative embodiment of the antenna system of FIG. 3 comprising two antennas.

  FIG. 3 schematizes an antennal system comprising a flat circular antenna 10 of inclined beam for example at a) = 45 with respect to its mechanical axis 12, itself inclined at 45 degrees with respect to the vertical of the place. The antenna rotates on its own mechanical axis 12, a motor 15 allows this rotation. The antenna is associated with a vertical axis of rotation in the bearing 11 also motorized 16. The other elements associated with the antenna and known to those skilled in the art, are not shown because they do not intervene in the understanding of the 'invention.

  According to this arrangement, a rotation of the antenna on its mechanical axis 12 runs the antenna beam 13 on a cone of 90 degrees of vertex, the beam passing through all the elevation values from horizontal to vertical ( low position antenna beam Faph and high position antenna beam Faph). The rotation of the antenna on the bearing axis makes it possible to orient the beam in all the bearing directions useful for aiming at a satellite.

  More generally, the inclination of the mechanical axis of the antenna with respect to the vertical of the location and the inclination of the antenna beam relative to the mechanical axis of the antenna, the rotation of the antenna on its mechanical axis makes it possible to reach all the values of elevations between (8 + c)) and (8 cf)) with respect to the vertical, ie an angular sector equal to 2 times the smallest value of 8 or cf), ie 2 times min (8, (p), for 8 = cp = 45 degrees, the beam thus takes all elevation values between 0 and 90 degrees as shown in FIG.

  In order to better understand the principle implemented in the invention, the following example relates to an integrated antennal system mounted on the fuselage of an airliner. In this application, the antenna system must have a small thickness to limit aerodynamic drag.

  Figures 4A and 4B show a sectional view and a perspective view of an antenna installed on a fuselage of an airliner, the dimensions of which are given by way of non-limiting example.

  The antennal system of FIG. 4 comprises two flat circular antennas 20, 21 of 50 cm in diameter, the antennas are arranged with respect to a support 22 which is assumed to be horizontal (in practice, the top of the fuselage of the aircraft). The value of the diameter respectively D, and D2 of the antennas is chosen for example as a function of the radio transmission application. Each of the antennas 20, 21 (plane of the antenna which is inclined) is inclined for example by an angle α1 = α2 = 20 degrees with respect to the support 22. Each antenna rotates on its mechanical axis, respectively 23, 24. The first antenna 20 has a beam inclined at an angle cpi = 60 and the second antenna has a beam inclined at an angle cp2 = 20. The assembly rotates in a bearing around a vertical main axis with respect to the support on which the antenna is positioned. All mechanical axes are motorized by means of engines not shown because they do not participate directly in the principle of the invention. The antennal system is protected for example by a radome 26 having a circular base of 1 meter in diameter and a thickness of 20 cm.

  According to this arrangement, the first antenna 20 covers the elevations of 10 to 50 degrees (40 to 80 degrees relative to the vertical 25), the second antenna 21 covers the elevations of 50 to 90 degrees (0 to 40 degrees relative to the vertical 25 defined above). The assembly makes it possible to reach all the elevations between 10 and 90 degrees (0 and 80 degrees relative to the vertical 25) and all the deposits from 0 to 360 degrees, ie the entire useful area for an airliner. .

  The space available under the flat antennas is available for example to house the various equipment connected to the antenna and to obtain a small integrated system.

Claims (5)

  An integrated antennal system for telecommunications comprising: at least one antenna (10) substantially flat and circular equipped with an axis of rotation (12) coinciding with its axis, the antenna (10) being secured to a support comprising even an axis of rotation (11) characterized in that the axis of rotation (12) of the antenna is inclined at an angle e with respect to the axis of rotation (11) of the antenna support and the beam antenna (13) makes an angle cp relative to the axis of rotation of the antenna and in that it comprises a device adapted to rotate the antenna and the antenna support 2 antennal system according to the claim 1 characterized in that the diameter of the antenna is selected according to the communication application.   3 antennal system according to claim 1 characterized in that the angle e is equal to 45 degrees relative to a second axis of rotation (axis of rotation of the support) substantially vertical, and the angle cp is equal to 45 degrees.   4 antennal system according to claim 1 characterized in that it comprises at least 2 flat antennas (20, 21) substantially circular in diameter (D1, D2), each of the antennas 20, 21 is inclined for example by an angle a1 = a2 = 20 degrees relative to the antenna support, and in that the antenna 20 has a beam inclined at an angle (p1 = 60 and the antenna 21 has a beam inclined at an angle (P2 = 20.     Antenna system according to one of claims 1 to 4 characterized in that it comprises a radome encompassing the antenna elements.   6 antennal system according to one of claims 1 to 5 characterized in that it is arranged on an aircraft fuselage.   Method for transmitting one or more antenna beams in a telecommunication system, characterized by rotating an antenna having a beam at an angle cp to the axis of rotation of the antenna antenna (12) and simultaneously rotate the axis of rotation (11), the axis of rotation of the antenna being inclined at an angle e with respect to the axis of rotation (11) of the antenna support .